条形柄锈菌吸器特异效应蛋白Hasp68抑制寄主免疫并与小麦组织蛋白酶B互作

作为活体营养专性寄生真菌,条形柄锈菌（小麦条锈病）在侵染过程中通过形成吸器向寄主细胞释放效应蛋白,干扰寄主的防卫反应,促进其侵染与致病。因此,条形柄锈菌效应蛋白的鉴定与功能研究对揭示其毒性机理具有重要意义。本实验室前期完成了条形柄锈菌CYR31生理小种吸器转录组分析,从中鉴定得到一个吸器特异诱导表达分泌蛋白Hasp68,利用农杆菌侵染在烟草细胞中瞬时表达该基因,能够抑制小鼠促细胞凋亡蛋白Bax诱导的细胞程序性死亡,鉴定为条形柄锈菌候选效应蛋白。Hasp68基因全长318bp,编码105_aa,N-端包含20_aa的信号肽,无保守结构域。BlastX分析表明Hasp68为条形柄锈菌特有效应蛋白,在其他真菌中无同源蛋白,且在条形柄锈菌16个菌系中呈较低的序列多态性,表明其在条形柄锈菌的进化过程中相对保守。借助荧光假单胞菌EtHAn的三型分泌系统,在小麦细胞中过表达Hasp68能够抑制由非致病细菌引起的PTI（PAMP-triggered immunity）相关胼胝质的积累;同时,也能抑制小麦与无毒条形柄锈菌互作中ETI（effector-triggered immunity）相关的活性氧爆发和过敏性坏死反应,表明效应蛋白Hasp68具有抑制寄主免疫反应的功能。利用酵母双杂交系统筛选Hasp68在小麦中的互作蛋白,发现其与组织蛋白酶B（cathepsin B）TaCTSB互作,双分子荧光技术进一步验证二者在烟草细胞中共表达存在互作,初步揭示了效应蛋白Hasp68的互作靶标。     

A single gene in Fusarium oxysporum limits host range

Fusarium oxysoporum f. sp. radicis-cucumerinum (Forc) is able to cause disease in cucumber, melon, and watermelon, while F. oxysporum f. sp. melonis (Fom) can only infect melon plants. Earlier research showed that mobile chromosomes in Forc and Fom determine the difference in host range between Forc and Fom. By closely comparing these pathogenicity chromosomes combined with RNA-sequencing data, we selected 11 candidate genes that we tested for involvement in the difference in host range between Forc and Fom. One of these candidates is a putative effector gene on the Fom pathogenicity chromosome that has nonidentical homologs on the Forc pathogenicity chromosome. Four independent Forc transformants with this gene from Fom showed strongly reduced or no pathogenicity towards cucumber, while retaining pathogenicity towards melon and watermelon. This suggests that the protein encoded by this gene is recognized by an immune receptor in cucumber plants. This is the first time that a single gene has been demonstrated to determine a difference in host specificity between formae speciales of F. oxysporum.     

Chloroplast clustering around the nucleus is a general response to pathogen perception in Nicotiana benthamiana

It is increasingly clear that chloroplasts play a central role in plant stress responses. Upon activation of immune responses, chloroplasts are the source of multiple defensive signals, including reactive oxygen species (ROS). Intriguingly, it has been described that chloroplasts establish physical contact with the nucleus, through clustering around it and extending stromules, following activation of effector-triggered immunity (ETI). However, how prevalent this phenomenon is in plant–pathogen interactions, how its induction occurs, and what the underlying biological significance is are important questions that remain unanswered. Here, we describe that the chloroplast perinuclear clustering seems to be a general plant response upon perception of an invasion threat. Indeed, activation of pattern-triggered immunity, ETI, transient expression of the Rep protein from geminiviruses, or infection with viruses or bacteria all are capable of triggering this response in Nicotiana benthamiana. Interestingly, this response seems non-cell-autonomous, and exogenous treatment with H₂O₂ is sufficient to elicit this relocalization of chloroplasts, which appears to require accumulation of ROS. Taken together, our results indicate that chloroplasts cluster around the nucleus during plant–pathogen interactions, suggesting a fundamental role of this positioning in plant defence, and identify ROS as sufficient and possibly required for the onset of this response.     

Function of Arabidopsis SWAP70 GEF in immune response

In animals, major classes of Rho guanine nucleotide exchange factors (GEFs) possess a Dbl (diffuse B-cell lymphoma)- homology (DH) domain that functions as a GEF-catalytic domain. However, no GEFs with the DH domain had been identified in plants. Recently, we found that the rice homolog of human SWAP70, Oryza sative (Os) SWAP70, containing the DH domain, exhibited GEF activity toward the rice Rho GTPase OsRac1, and regulates chitin-induced production of reactive oxygen species and defense gene expression in rice.¹ Arabidopsis contains a single SWAP70 gene. A T-DNA insertion mutant of Arabidopsis SWAP70 was morphologically wild type. Measurement of in planta growth of Pseudomonas syringae DC3000 hrcC, a mutant incapable of type III effector delivery, revealed enhanced growth of the pathogen in the atswap70 mutant, indicating that AtSWAP70 is required for PAMP-triggered immunity. In addition, the atswap70 mutation reduced the RPM1-mediated hypersensitive response. These results suggested that AtSWAP70 plays a role in both PAMP- and effector-triggered immunity in Arabidopsis.     

A single region of the Phytophthora infestans avirulence effector Avr3b functions in both cell death induction and plant immunity suppression

As a destructive plant pathogen, Phytophthora infestans secretes diverse host-entering RxLR effectors to facilitate infection. One critical RxLR effector, PiAvr3b, not only induces effector-triggered immunity (ETI), which is associated with the potato resistance protein StR3b, but also suppresses pathogen-associated molecular pattern (PAMP)-triggered immunity (PTI). To date, the molecular basis underlying such dual activities remains unknown. Based on phylogenetic analysis of global P. infestans isolates, we found two PiAvr3b isoforms that differ by three amino acids. Despite this sequence variation, the two isoforms retain the same properties in activating the StR3b-mediated hypersensitive response (HR) and inhibiting necrosis induced by three PAMPs (PiNpp, PiINF1, and PsXeg1) and an RxLR effector (Pi10232). Using a combined mutagenesis approach, we found that the dual activities of PiAvr3b were tightly linked and determined by 88 amino acids at the C-terminus. We further determined that either the W60 or the E134 residue of PiAvr3b was essential for triggering StR3b-associated HR and inhibiting PiNpp- and Pi10232-associated necrosis, while the S99 residue partially contributed to PTI suppression. Additionally, nuclear localization of PiAvr3b was required to stimulate HR and suppress PTI, but not to inhibit Pi10232-associated cell death. Our study revealed that PiAvr3b suppresses the plant immune response at different subcellular locations and provides an example in which a single amino acid of an RxLR effector links ETI induction and cell death suppression.     

两类免疫受体强强联手筑牢植物免疫防线

植物先天免疫系统在抵御病原菌入侵过程中发挥至关重要的作用, 主要包括两个层次, 即病原菌相关分子模式和效应因子分别触发的PTI和ETI免疫反应。PTI和ETI分别由植物细胞膜表面模式识别受体(PRRs)和胞内免疫受体(NLRs)激活, 具有特异的激活机制, 但是两者激活的下游免疫事件相互重叠。PTI和ETI是否为泾渭分明的两道防线, 以及ETI与PTI下游事件为何如此相似, 一直是植物免疫领域最受关注的问题之一。最近, 中国科学院分子植物科学卓越创新中心辛秀芳团队与合作者利用拟南芥(Arabidopsis thaliana)与丁香假单胞杆菌(Pseudomonas syringae)互作系统对PTI和ETI在机制上的联系进行了研究。他们发现PRRs和共受体参与ETI, 而活性氧的产生是联系PRRs和NLRs所介导的免疫早期信号事件。他们还发现NLRs信号能够迅速增强PTI关键因子的转录和蛋白水平, PTI的增强在ETI免疫反应中不可或缺。该研究从机制上解析了植物免疫领域中长期悬而未决的PTI与ETI相似性之谜, 是该领域的一项突破性进展, 为未来作物分子设计育种提供了新的启示。     

Role of small RNAs in the interaction between Arabidopsis and Pseudomonas syringae

Endogenous small RNAs (miRNAs and siRNAs) regulate gene expression in diverse biological processes.Research with the Arabidopsis-Pseudomonas syringae system has shown that small RNAs contribute to plan...